Triple valve for air brake systems



Aug. 13, 1935. B. PRATT 2,011,343

TRIPLE VALVE FOR BRAKE SYSTEMS Filed Deo. 22, 1930 5 Sheets-Sheet l Aug. 13, 1935. B. PRATT I TRIPLE VALVE FOR AIR BRAKE SYSTEMS 5I 'Sheets-Sheet 2 Filed Dec. 22, 1930 Aug. l13, 1935. B. PRATT TRIPLE VALVE FOR AIR BRAKE SYSTEMS Filed Dec. 22, 1930 5 Sheets-Sheet 3 l dike/M4110 ug 13, 1935. B PRATT 2,011,343

TRIPLE VALVE FOR AIR BRAKE SYSTEMS Filed Deo. 22, 19304 5 Sheets-Sheet 4 Aug. 13, 1935. B. PRATT 2,011,343

TRIPLE VALVE FOR AIR BRAKE SYSTEMS Filed DSC. 22, 1930 5 Sheets-Sheet 5 @QLD G55 Patented Aug. 13, 1935 TRIPLE VALVE FOR AIR BRAKE SYSTEMS Best Pratt, Chicago, Ill., assigner to Brake Equipment & Supply Company, Chicago, Ill., a corporation pf Illinois Application December 22, 1930, Serial No. 504,161

15 Claims.

The present invention relates to fluid pressure brakes and more especially to improvements in the construction and operation of the present K type triple valve.

Heretofore, it has been diicult to provide a cations of the brakes only when required land in 5 fluid pressure brake capable of effectively preorder that serial action in emergency applications venting undesired emergency action, due to the maybe obtained even after a full service applicafact that the various parts necessary to provide tion has been made. this action were incorporated in the triple valve A further object consists in the provision of a and were operated by the'parts which provide the service measuring chamber or service reservoir 1dV usual service braking operation. The difference which, in the present construction, is shown as a betweenthe rate of brake pipe reduction to operseparate body to the main valve body of the ate the triple valve piston, slide valve and other triple valve and which, upon the actuation of the parts tota position to provide for service braking main Valve and its associated parts, is arrange-d was so near to the rate of brake pipe reduction to selectively communicate with the train pipe or 1'5 to provide for emergency braking that any dethe atmosphere, so that the service reservoir is rangement of parts, lack of lubrication or colleccut off from communication with the brake pipe tion of dirt or other foreign matter caused the and put into communication with the atmosphere triple valve piston and slide valve to assume a when the main or triple valve is in its normal and 2O. position which resulted in emergency applications retarded release positions and is cut off from 20 When a service application Was desired. communication with the atmosphere and placed In order to apply the brakes more uniformly in communication with the train pipe when the on long trains, it has been found necessary t0 triple valve is moved to a position for causing reduce the rate of build-up in the brake cylinder the 'brakes to be applied. The service reservoir pressure, since the serial action in any emergency is of predetermined size or capacityso that the 25 aDDCatiOIl Will run through a 100 car train in volume thereof is in exact accordance with the approximately ten seconds.v Volume and length of the brake pipe on each car An important object of the present invention of the train, in order that a uniform and predeconsists in incorporating in a separate valve the termined amount of brake pipe reduction will be means by which the brake pipe pressure is reduced eifected at eachv chamber, when the main valve is 30 in serial action at a suicient rate an amount to moved toI its service position, thus insuring a insure the movement of the triple valve piston positive quick service application and eliminatingA and slide valve to a position where the brake the undesired emergency action typical to these cylinder pressure will be obtained to a predetertypes 0f valves, i mined 81110111113 and ai a pi'lileellfnnedr Tate O Other objects and advantages of the invention 35. time. will become apparent from the following descrip- A further Object CODSSS in the lHOVSOn 0f tion when taken Vin conjunction with the accommeans whereby the pressure in the brake cylinder panyng @191mg i is built up more slowly than 011 the present K Referring to the drawings, in which is shown a, type triple valves and the serial action accelerprefefred embodiment of the invention, 40 40 ated, S0 that Ehe brakes Wm be applied more um* Figure 1` isa side elevational View with parts formly and Wl'hout any Slack atlon; in section of the present K type triple system Another object of the invention 1s toprovide with the invention applied thereta agulck servlce attachment for standard K type Figure 2 is an enlarged Sectional View of the le Slagtucnta'e sdlleglgor: triple valve in its normal released position. 45`

v anism, .said attachment being so constructed and lgure 3 1S a' sectlonal View of the tuple Valve arranged that the main or triple valve and its m 1t s retarqed relea'ed pomon' Y associated parts may be easily changed or re-` Figure .1S a' Setlonal YleW of )Phe tmpl@ Valve designed, in order to co-act therewith in the opm lts posmve qulck Servlce posltlon' eration oi the brake equipment without the neces- Fgufe 5 is a Sectional View 0f the tiple Valve 50 sity of incorporating an entirely new triple valve m its emergency position mechanism. v Figure 6 is an enlarged sectional view of the A further object comprehnds the provision of Vent valve mechanism. means for discontinuing 'the emergency feature Figure 7 is abottomA plan view of the main slide in ltriple valves by blanking 'off the usual commu-v valve. v 1 55 nication between' the train pipe and the brake cylinder and incorporating the emergency feature in an independent vent valve, so as to provide means for preventing the emergency applivalve. l

Figure 9 is a bottom plan View of thergraduating valve. Y Figure 10 is a bottom plan view of the valve seat.`

Figure 11 is a top plan view` of the valve seat. Figure 12 is a diagrammatic plan view showing the position of the slide valve and graduating valve relative to the sllde valve seat, when the valve is in its retarded release position.

Figure 13 is a View similar to Figure 12 with the valve parts in their normal release position.

Figure le is a view similar to Figure 12 with the valve parts in their service-position.

Figure 15 is a view similar to Figure 12 with the Valve parts in their emergency position.

Figure 16 is a detail sectional view of a modi-` fied form of the invention.

Referring to the drawings, in which like numeralspindicate like parts in the several views and more particularly Figure 1, irdesignates the train pipe which is locally connected to the brake equipment of each car by the brake pipe I I, which is connected to the standard K type triple valve body I2 bythe coupling I3. An angle cock I4 may be provided for controlling the flow of the train pipe pressure `through the brake pipe II. A branch pipe I5 connected to the pipeY II as at I6, communicates with AVan independent vent valve chamber Il. The train pipe may also be provided 4with the usual centrifugal dirt. collector I8 for treating the air prior to its introduction into the triple valve casing I2.

The triple valve casing I2 may be connected to the auxiliary reservoir I9 by the' bolts 20, While the brake cylinder 2I'is attached to the auxiliary reservoir by the bolts 22 and may have the pipe 23 extending through the auxiliary reservoir to communicate with the body.

Train pipe pressure is admitted into the triple valve and auxiliary reservoir from the chamber 25 through a passage 26 into the head or cap 21 and the opening 28, so as to empty into the piston chamber 2 9. Mounted in the chamber 29 is the triple valve piston 39 having its stem 32 (Fig. 2) extending into the slide valve chamber 33. The

passage 24 in the valve piston chamber 29 is provided with a bushing 34 having an axiallyV disposed notch or groove which, when the piston is in its retarded and nor-V mal release positions, as shown in Figures 2 and 3,

allows the train pipe pressure to ow through the slidable valve chamber 33, yieldable stop housing 35 and into the auxiliary reservoir- I9. When the pressures on both sides of the piston 3.0 are equalized, the system is then considered to be charged. The triple valve piston stem 32 has a, reduced portion 31 positioned between the annular stop collar 33 and the end flanges or spaced arms 39 and this reduced portion is provided with a recess 4U, which carries the graduating valve 4I that co-acts with the main slide valve 42 for moving the various ports and passages into and outv of communication with one another during the operation of the triple valve. ,The main valve 42 is slidably mounted on a hollow valve seat 43 and is arranged to abut at its opposite ends the collar 38 and arms 39 respectively, so that upon movement of the valve stem 32 alimited distance relative to the main valve 42, the main valve will be moved bodily a predetermined distance in either direction with the graduating valve. The construction and operation of the foregoing parts are similar to the usual construction of the present type triple valve now in general use and perform the usual functions in response to changes in train pipe pressure, thebrakes being released and the auxiliary reservoir charged when pressure is admitted to or increased in the train pipe and the brakes being applied when the train pipe pressure is reduced; the train pipe pressure being under the control of the engineer by a suitable engineers valve. In order that the movement of the main valve. stem and its associated parts may be clearly` understood they will be referred to as shown in the drawings.

In order to insure positive quick service application of the brakes and provide an equipment that gives an emergency application only when necessary, I have reorganized the standard triple valve construction in such a manner that these standard parts may be altered and used. with my present attachment and the changes necessary may be economically effected at minimum expenditure of time and labor. Moreover, Il have discontinued the emergency featurerandl have substituted therefor an attachment which may be readily installed or associated with the body of the triple valve. In discontinuing the emergency valve and its associated parts, I have. modiiied the auxiliary chamber or the quick action piston chamber 44 positioned between the train pipe II and brake cylinder passage 24 by providing the chamber 44 with a' bushing 45, so as to permanently' blank communication 'between the train pipe and brake cylinder. The auxiliary chamber 44 communicates through a passage 45 with the slidable i valve chamber 33 and auxiliary reservoir in a manner which will subsequently be de# scribed, and is provided with a service piston 47 having a depending boss 48, to which is connected a stem 49 that extends through a guide sleeve 5i) carried by a closure member 5 I, that is fixedly secured to the valve body I2. The lower end of the stemr49 projects into a service chamber 52 that has mounted therein a poppet or `vent valve chamber 53, that is provided with a. valve seat opening engase- 'n Y diameter than the valve opening so as to form Y a clearance therebetween to permit the air to pass from the chamber 53 tothe chamber 52 'when the valve 55 is moved away from its seat. Train pipe pressure is conducted from the chamber 25 of the valve body through a restricted opening or passage 59 to the chamber 53.

. In order to insure positive serial action in service application of the triple valves,.there is provided a service reservoir,A or service measuring chamber 6I] (Fig. 1) 'which communicates with the service chamber 52 through the pipe 6I as at 62. As shown, the service reservoir is independent of the main valve body, but, if desired,

may be incorporated as a part of the main valve body.

The construction and operation of the triple valve is such thatthe service reservoir or service measuring chamber 60 is out of communication with the train pipe whenY the triple valve isrin its released'position, in which position it remains at intervals between successive applications of the brake.` Itv will, therefore, be seen that when the service chamber 52, is placed in communication with the brake pipe II, it` increases the capacity of the brake pipe and allows the brakelpip'e air to assumeV a larger volume which proportionately reduces the train pipe pressure, causing a preponderance of pressure on the auxiliarylr reservoir side of the piston 30. The pressure in the train pipe and the service reservoir 60 quickly equalize and since the service reservoir is of la predetermined capacity, the amount of train pipe reduction in each car is definite vand uniform throughout the train, the percentage of reduction depending upon the relation of the capacity of the service reservoir 60 to the-proportional part of the brake pipe pertaining to the same car equipment. This drop in pressure in the brake pipe leaves the auxiliary reservoir 'pressure in preponderance, causing the move ment of the triple valve and its associated'parts to the left (Fig. 2). Y

,The valve seat 43 is provided with a through opening`63 (Fig. 1l), which terminates in the bottom face of the valve seat in an elongated cavity 64 that communicates with the brakecylinder passage 24. An opening 65 in the valve seat registers with the passage 46 that leads from the service chamber 44 at a point above the piston 41 (Fig. 2) An opening 66 in the valve seat communicates with a passage 61 in the valve body that extends from the service chamber 52, while a restricted opening 58 in the valve seat communicates with an exhaust port 69 in the valve body that leads to the atmosphere.

In order that the various positions assumed by the triple valve and its associated parts may be clearly understood and as it is difficult to show,V in sectional views, the various ports or passages that are-moved into or out of registration in the diiferent positions assumed by the triple valve, due to the fact that certain of these ports are in transverse alignment or slightly offset relative to one another, reference will be had to Figures '7 to 15 inclusive, to show the exact position of the various ports andcavities during the operation of the triple slide valve.

Referring to the main slide valve 42 `and more particularly Figure 8, the top of the main valve is provided with a port 1D that communicates with a diagonally disposed longitudinal passage 1| that is drilled in the body of the slide valve and terminates in the end face 3| of the slide valve adjacent the collar 38, (Fig. 2). The top of the valve also has a through opening 12, an elongated transversely disposed opening 13 and a through opening 14, while the bottom face of the 'main valve 42, as shown in Figure 7, is provided with an elongated cavity 15, which extends parallel to one side thereof and has a transversely disposed branch cavity 16, which terminates in a longitudinally extending cavity 11 parallel to the cavity 15, but of lesser width and length. The transverse cavity 16 is also provided with a laterally offset cavity 18, while the cavity 15 at one end communicates with a cavity v19 by a reduced passage 80. The passage 12 terminates on the bottom face of the valve in a substantially L-shaped cavity 8|, (Fig. 7), while the cavity 13 on the bottom face ofthe valve is formed with a longitudinal offset cavity 82. The opening 14 has the lower end thereof terminating` in an elongated cavity 83. The graduating valve 4| in the bottom face thereof has a transversely disposed recess 84 arranged upon movement of the stem 32 to close and establish communication between the port and the opening 12 and also to' open and close the opening 13;

` auxiliary reservoir I9.

YRetail-ded release position In order that the various positions assumed by the main valve 42v and graduating valve 4I relative to one another and to the ports in the valve seat when the triple valve piston 30 and its stem 32 are actuated, it will be first assumed that the triple valve piston'30 and its associated parts are in the retarded release position, as shown in Figures 3 and 12. In this position, compressed air from the train pipe passes from the chamber 25 and passage 26 in the valve body I2 into the head 21, through the opening 28 into the piston chamber 29, and past the feed groove 35. It will be noted that the piston 3Dis moved into abutting engagement with the adjacentl end of the slide valve seat 43, so as to restrict the flow of air from the train pipe into the slide valvechamber 33 and The inner face of the piston 3e adjacent its engagement with the valve seat 43 is provided with a groove 85, which allows a restricted flow of air to pass from the chamber 29 into the chamber 33. The graduating valve 4| and main slide valve 42 are carried by the valve stem 32 to the position as shown in Figure 3, in which position all the ports are blanked for the admission of the auxiliary reservoir air` to the brake cylinder. The brake cylinder pressure is permitted to exhaust to the atmosphere through the port 24, which communicates with the cavity 64 on the underside of the slide valve 43, which, in turn, communicates through the opening 63 with the cavity in the bottom of the slide valve 42 and is conducted through the restricted opening 8i! to thecavity 19, that registers with the opening 66 in the valve seat, which communicates with the exhaust opening 69 in the valve body. Pressure is also exhausted from the cham-` AtV the same time, pressure from the service chamber 52 passes through the passage 61 to the opening 68, which is in registration with the offset cavity 18 in the bottom of the slide valve 42, Vso'that the pressure in the service chamber 52'is conducted from the passage 16 through the restricted opening 8!! and cavity 19 in the bottomv face of the slide'valve 42 to the opening 66 in the valve seat, which empties into the exhaust port 69 in the valve body.

It will be noted that in the retarded release position the exhaust ofthe brake cylinder pressure to the atmosphere is restricted through the relatively small port 80 in the slide valve, so as to prevent `the brakes on the forward end of the train from releasing as readily as if the triple valve went to the normal release position and without compressing the retarded release spring 86. Also, in thisposition the feed groove 35 has not its full capacity due to the fact that the face of the piston 3!! engages the adjacent end of the slide valve seat 43 and the auxiliary reservoir is restricted in its charging by the small port or groove 85 in the face of the triple valve piston 30.

N ormai release position,

In this position, as *shown`r in Figures 2 and 13,

the retarded release spring 86 moves the slidey valve to a position where the brake cylinder pres- 4 port 24, cavity64, and opening 6`3`in the-valve seat 43V that communicateswith the cavity .15

'which'has `been kmoved into registration with the V42 which communicates with the cavity 1 5 thatL empties throughthe opening 86 into the exhaust S9. The service chamber 52 is also opened to the atmospherek through the passage 61 and openingV 6 8 that communicate with the transverse cavity 1G in thebottom face of theV slide valve 42, which, in turn, empties intoL the cavity 15 that registers with .the opening 65 thatcommunicates with the exhaust port 69. It will be noted that in the retarded release position, the brake cylinder pressure, the pr'essurein the auxiliary chamber 4 4 and. service chamber 52, Aempty intothe exhaust lthrough the cavityj19 in the bottom face of the slidevalve 42, While `in the normal release position the slide valve 4 2Mhas been moved aflimited distance, so` that Vthe cavity 19 is closed frein communication with the atmosphere and cavity 15 is moved into registration with the opening 56 that aligns with theexhaust cavity 69. Y y Y Positive service position Upon a reduction of train pipe pressure by the application of the engineers valve, a preponderance of pressure is established on ithe slide valve chamber 33 side of the rpiston 3D, which causes i the triple valve pistonv and its associated parts to be moved to the position shown in Figure 4, with the main slide valve 42 and auxiliary valve 4| in register with theports as more clearly disclosed in Figure le. In thisposition, the'in'itial movement of the piston and itsvalve stem 32`v towards the left causes the graduating valve 4| to bemoved relative to theV main slide valve 42, sothat the cavity 84 in the bottom face of the graduating valve registers with the port 10 and opening 12, while the main slide valve has been moved relative to the slide "valve seat 43 to bringV the opening 12 into registration'with the opening 65in the slide valveseat, thus establishing communication between the slide valve chamber 33 in front of the piston 41 with the auxiliary chamber 44, through the longitudinalextending opening 1| in the slide valve 42, ports 10Vand 12, which are connected through the cavity 84 on the graduating valve 4|, the opening 65' in the valve seat with the passage 46 leading 'to the (chamber 44, thus forcing the service piston 41 and its stem 49 downwardly which, Vin turn, 4moves the valve 55 away from its seat 54, thus permitting the train pipe pressure in the poppet'valvechamber 53 to pass into the service chamber 52 from where itis conducted through the pipe 6| to the service 'reservoir'tl Since the volume of the quiclrjservice measuringY chamber 60 is in exact accordance with the volume4 of the brake pipeon each car, pressurewill-'be reduced immediately. a suiicient` amount to move promptly the piston 3|! and its associatedpartsY to theserviceposition.` The-capacity of the port 59in the poppet valve is of a predetermined size, so lthat the ow of air from the brakefpipe tothe .service chamber 52 takes place in exactly the right timeV Without interfering with the triple action of the emergency valve. Upon this positive drop in brake pipe pressure, the; mainv slide valve 42, k is carried to itsserviceposition permitting the air.

gasket '93.

to pa'ssgfromV `the "auxiliary reservoir |'9 and slidable `valve ,jchamber 33 -to the brake cylinder 2| through the opening13 inthe main slide valve, which registers with the opening 63 in the valve seat 43 that communicates with the, passage 24 leading to the brake cylinder through the cavity 64., It will be noted that'in this position-the graduating valve 42 is moved.- away from the opening 13. When the pressurein the auxiliary reservoir is reduced slightly below., that in the brake pipe, the piston 30 and the graduating valve. 4| are moved to the right from the position, as shown in Figure'4, so that thegraduating valve will blank the opening 13 inthe main valve, thus cutting oif the ilowv ofA air from the auxiliary reservoir to the brake cylinder. In order Y vided'with a rubber seat 81 arranged to form ar joint, as at 38, with the adjacent end ofthe ysleeve'or bushing 50 when the triple valve is in this position, thus preventing the escapeof any air from the auxiliary chamber 44 into the'service chamber 52 and service measuringl chamber 60 during the actuation of the service piston 41. It vwill benoted that by reason ofthe structural arrangement o'f parts, a positive reduction of brake pipe pressure is insured upon the initial movementof the graduating valve 4| and slide valve 42, which takes place slightly in advance of the opening of the lport 13 in the slide .valve'which establishes communication between the auxiliary reservoir and the brakecylinder, thus insuring a positive movement ofthe triple'valve piston 30 to its service position. The volume of the service chamber 60 is in exact accordance with the length and volume of the brake pipe on each car, so that a uniform-and predetermined amountof brake pipe reduction takes place in each chamberas itis applied.' The service chambers are preferably marked in accordance with the-length of the brake pipe of the train.

It will be noted that fin the reduction of brake pipe pressurel in this manner, 'thes'erial action in service application ofthe triple valvewill be materially decreased, so that the brakes on either a long passenger or freight train may be applied in service application before the slack is'bunched, thus avoiding severe shocks rto the running gear of the train, which is caused by unequal application of the brakes at the head and rear of the train.`

Emergency position The piston 3 0 isshown in the emergency position in Figures 5 and l5, in'whichpositionfthe main slide valve 42 and graduatingvalve 4| have been moved by the piston stem 32 to assume their eX- treme left position, due to the preponderance of pressure in the slide valve chamber'33` and auxiliaryreservoir chamber, sof that the end 89 of the graduating stem S0 in the headj21, is engaged by the adjacent abutment 9| of the piston and moved to theleft against the tension of the spring 92, thus forcing the adjacent face of the piston 30 closely adjacentto the gasket 93. Of course, it is understood that when the piston 3E! reaches its extreme left position, vit engages the In this position, the slide valve 42 has been moved, so that the port 14 therein registers with'the opening `63 in thervalve seat, to

' establish communication betweenV the auxiliary reservoir andthe brake cylinder through the cavity 64, which immediately appliesr the brakes. In this position, the auxiliary lreservoir' pressure is allowed to equalize with the brakeV cylinder pressof sure, due to the factthat the slide valve 42 and piston 30 remain in this position', because the brake pipe pressure is depletedto zero, when an emergency application is made. The size of the port 'lil and the. slide valve 42 determines the rate of build up in the brake cylinder pressure and this port should be of such a size to permit the brake cylinder pressure building up, so that the slack will not run through the train.

Since the brake pipe pressure is reduced in advance of the movement of the slide valve, the brakes may be applied in service application, as fast or faster, than the slack will run on a long train. This is highly desirable as it has been Ifound that the slack will run either in or out at slow speeds in approximately seven seconds with a 100 car train.V

Vent valve operation {As the brake pipe pressure builds up in the pipe it flows through the pipe l5 into the vent valve chamber I1 through the passage 94 (Fig. 6), into a chamber 95 that communicates through the opening 96 with chamber 91 and through the opening 98 with chamber 99, so as to impinge upon the left face of the vent piston |00 and force the same to the right until the head |0| on thepiston stem |02 engages the stop plate |03. The vent piston |00 is then in its full release position and the pressure in chamber 99 on opposite sides of the piston |00 is allowedto equalize by means of the radial lopening |04 in the steml 02, which communicates -with the axial opening |05, that extends to the exposed right end or face of the piston 99. .The exhaust chamber |08 in the vent valve casing communicates with the chamber 91 through the valve seat passage |01, which passage is normally closed by the vent valve |08, which khas a stud |09 between which and the opposed wall ||0 is confined a coil spring for yieldably maintaining the valve |08 in its closed position. Upon a sudden or heavy reduction of pressure in the brake pipe the drop in pressure in chamber 91 will cause a preponderance of pressure in the chamber 99 on the right face of the valve |00. The greater pressure on the right face of the piston |00 will force the stem |02 to the left against the tension of spring compressing thevlatter and moving the vent valve |08 away from its seat, so as to establish communication between the train pipe pressure and the exhaust |08, thus depleting the brake pipe pressure and causing an instantaneous and simultaneous application of the brakes throughout the train. As the pressure equalizes in the chamber 90 on opposite sides of the piston |00 through theports |00 and |05, such equalization destroys the resistance to the spring so that the latter, upon overcoming this pressure, forces the vent valve |08 to its seat, closing communication through the exhaust |06 and the atmosphere.

It will be observed that my improved attachment may be readily connected to the present K type triple valves with slight alteration to the triple valve and its associated parts and is arranged to supplant the ordinary emergency valve usually employed with this type of valve construction. Moreover, by discontinuing the emergency feature of the standard Kv type triple yvalves and incorporating it in an inde- Y pendent vent valve, serial action in emergency applications maybe obtained even Aafter a full service application has been made. Additionally,

l byreason o f the present invention, a simple, enicient and economical attachment is provided that may be installed on the present type of triple valves for venting brake pipeair pressure locally into a predetermined size service reservoir,

whereby the attachment and ports governed by,V

the actuation of the triple valve co-act to cut off communication of the service reservoir with the brake pipe and put it in communication with the atmosphere when the triple valve is in its normal and retarded release positions and cut off communication with the atmosphere andplace the service reservoir in communication with the train pipe when the triple valve is moved to a position for causing the brakes to be applied and whereby the auxiliary reservoir is placed vin communication with the brake cylinder after communication has been established between the brake pipe and the service reservoir. Moreover, the triple valve and its associated parts are so constructed and arranged that the brakes are applied in service application faster than in emergency application. In other words, the escape of air from the auxiliary reservoir to the brake cylinder is so regulated as to avoid or preclude the emergency application of the brakes when the triple valve and its associated parts are moved to service position to apply the'brakes.

Instead of altering the emergency chamber of `the standard K type triple valve to accommodate the service piston 41 and its associated parts, thelsame may be positioned in a separate casing y| |2V (Iig'. 16). This form of the invention is substantially similar in construction and operation to the parts previously described with the exception that the service piston ||3 has its stem ||4 extending through a hollow boss or sleeve ||5, that is preferablyV formed integral with the closure member that separates thefauxiliary chamber from the service chamber H8. Additionally, the casing may be provided with a passage f||9 arranged to selectively establish communicationvbetween the auxiliary reservoir and the brake cylinder during the operation of the main valve.

Y It is to be understood that the forms of invention shown and described are merely illustrative of preferred embodiments and that such changes as fall within the purview of one skilled in the art may be made without departing from the spirit of the invention and the scope of the appended claims.

WhatI claim is:

1. In a triple valve having a piston actuated by variation in train pipe pressure, a device supplanting the usual emergency mechanism to produce a positive quick service application comprising an auxiliary chamber having a bushing for closing communication between the train pipe and the brake cylinder, a service chamber beneath said auxiliary chamber, a piston in said auxiliary chamber having its stem extending into said service chamber, a poppet valve chamber communicating with the train pipe and provided with a valve seat for controlling communication between the same and the service chamber, a movable valve for said seat, said poppet valve having its stem extending upwardly into said service chamber and into engagement with the stem of said piston, means for normally Vurging said poppet valve into engagement with its seat, a service reservoir communicating with said service chamber, and means operable by the triple valve whereby the service reservoir is cut 01T from communication with the brake pipe and put in communication with the atmosphere when the triple valve is in its retarded and normal release positions, and placed in communication withthe vtrain pipe and cut off from the atmosphere when ing an auxiliary chambena service chamber and a poppet valve chamber, said poppet valve chamber communicating with the train pipe, a service reservoir communicating with said service cham- Y ber. and means operable bythe triple valve whereby the service reservoir isv cut oi from communi- Vcation with the brake pipe andk put in communication Vwith the atmosphere when thek triple valve isin its retarded and normal release positions, and placed in communication with the train pipe and cut-off from the atmosphere when theV triple valve is movedto a position forcausing the brakesto be applied.` i

3. A device to be applied to triple valves toy produce quick service application having a xed bushing in the quick action piston chamber for permanently closing the usual communication between said `chamber and the brake cylinder, a

service measuring chamber arrangedVv to selectively communicate with "the train pipe land the atmosphere, said device havinga valve for controlling the supply fromthe trainpipe to thel `service measuring chamber, said quick action pis'- ton chamber having a'reciprocating piston provided with'a stem for controlling saidivalve, and means operable by the Vtriple valve wherebygthe service measuring chamber is cut 01T from com'- munication with'the'fbrake pipe and put` into` communication'with the atmosphere when the triple valvev is in its retarded and normal release position, and placedin communicationwith .the

train pipe and cutoff from the' atmosphere when the tripler valve is'moved to a position for causing the brake to be applied.

4.` A device to be applied to triple valves for supplantingthe usual emergency mechanism to l produce a positive quick service 'application comprising an" auxiliary chamber interposed between theV passage communicating `the train pipe with the brake cylinder, a bushingY in said chamber forclosing communication between the train pipe and the brake cylinder, means communicatingl the auxiliary chamber with the auxiliary reservoir, a service chamber beneath said auxiliary chamber, a piston in said auxiliary chamber having itsstem extending into saidservice chamber, a poppet valve controlling the supply ofY train pipe 'pressure to the service chamber, agservice reservoir communicating with the service chamber, and'mea'ns cperable'byl the triple valve for causing the actuation of theV piston, whereby the' service reservoir is cut off from communication with the brake pipe and putin communication with the atmosphere when'theV triple -valve is in its retarded and normal release positions, 'and placed in communication with the train pipe and cut off from vthe atmosphere'when the triple valve is moved to a position for causing the brakes f to be applied. Y 5. A device Ato be'applied/ to triple valves for supplanting the usual emergency mechanism to produce a positive quick service application Ycomprising an auxiliary chamber interposed between theV passage normally establishing communication between the trainipipe and thel brake cylinder, means vin said'chamber for closing communication between the train pipe and' thebrake cylinder, means communicating the auxiliary chamber with the auxiliary reservoir, a service lchamber associated with said auxiliary chamber, a. poppet valve for controlling the ow of pressure from the train pipe to the service chamber, and means in said auxiliary reservoir and operatively connected to said poppet valve, whereby the service reservoir is cut off from communication with the brake pipe and put in communication with the atmosphere whenfthe triple valve is in its reltarded and normal release positions, and placedV in communication with the train pipe and cutv off from the atmosphere when the triple valveA is moved to a position for causing the brakes to be applied.y

6. In a triple valve having a piston actuated' by variation in train pipe pressure, a device supplanting the usual emergency mechanism to produce a positive quick service application com'- prising an auxiliary chamber positioned between the train pipe and the brake cylinder and com.`v municating with the triple valve chamber. a bushing in said auxiliarychamber permanently blank-V ing communication between theftrain pipe and.

brakemcylinder, a service piston .in said auxiliary chamber responsive to the pressure in the triple valve chamber, a service chamber, a closurermember having a medially disposed tubular sleeve for ,establishingl communication between said auxiliary chamber and said service chamber, said 'service piston having a depending stem extending rthrough said sleeve into said 'service chamber and provided with aseat for engagement with the adjacent surface of said sleeve, a poppet valve casingfcommunicating withy said service: chamber and provided'with a valve seat, a, kvent v alve co-acting with said valve seatVv for controlling the-pressure supply from the poppet valve to the service chamber, said poppet valve having its stem extending through 'said seat and into engagement with said vservice piston stem, yieldable means normally maintaining said poppet valve in engagement municatin'g the poppet valve with the train pipe pressure, a service reservoir communicating with the service chamber, andY meansr operable by the'y triple valve for actuating said service piston and said check valve, whereby the service reservoir is cut oif fromcommunication with the brake pipe and put in communication with the atmosphere when the triple v alve is in its retarded and normal release positions, and placed in communication'with the train pipe and cutY off from the position to apply the brakes.

7.' In'a triple valve having a piston actuated by variation in train pipe-pressure, a device substituted for the usual emergency mechanism to produce a positive quick service application comprising a hollowmember interposed between the Itrain pipe and the Vbrake cylinder and permanently blanking communication between the train pipe and brake cylinder, a service reservoir arranged toV communicate selectively with the Vtrain pipe and the atmosphere, and lmeansrin said hollow member and responsive VVto the pressure inthe auxiliary reservoir forcontrolling Ithe flow of the train pipe pressure to the service reservoir Whereby the service yreservoir is cut oi from communication with the brake pipe and put in communication with the atmospherewhen the triple valve is in its retarded and normal release positions, and placed in communication with the'train pipe and cut off :from the atmosphere when the triple atmosphere when the [triple valve is moved to` with its seat, means com-l valve is moved to a position to apply the brakes.

8. A device for triple valves arranged to supplant the usual emergency mechanism comprising a hollow member applied to the body of the triple valve, a service reservoir communicating with said hollow member and arranged to communicate with the train pipe and the atmosphere, said hollow member having movable means therein operable by the pressure inthe auxiliary reser- Voir for communicating the service reservoir with the atmosphere and cutting off its communication with the brake pipe when the triple valve is in its retarded and normal release positions, and placing the service reservoir in communication with the train pipe and cutting 01T its communication with the atmosphere when the triple valve has moved to a position to apply the brakes.

9. In combination with a triple valve having a triple valve piston actuated by variation in train pipe pressure, a hollow member forming part of the valve body and communicating with the auxiliary reservoir, said member positioned in the passage normally communicating the train pipe with the brake cylinder, and permanently blanking communication therebetween, a service reservoir adapted to communicate with the train pipe and the atmosphere, means in said hollow member and actuated by the triple valve piston for placing' the service reservoir in communication with the atmosphere and cutting ofi communication with the brake pipe when the triple valve is in its retarded and normal released positions and placing it in communication with the train pipe and cutting orf communication with the atmosphere when the triple valve is moved to its brake applied position, and means when the triple valve piston is in its retarded release position for restricting the flow of pressure from the train pipe to the auxiliary reservoir.

10. In combination with a triple valve, a hollow member forming part of the valve body and communicating with the auxiliary reservoir, said member positioned in the passage normally communicating the train pipe with the brake cylinder, and permanently blanking communication therebetween, a service reservoir adapted to communicate with the train pipe and the atmosphere, a service piston mounted in said hollow member and responsive to the pressure in 'the slidable valve chamber, a poppet valve for controlling admission of train pipe pressure to the service reservoir, and means operatively connecting said service piston to said poppet valve whereby the service reservoir is cut ofi from communication with the brake pipe and put in communication with the atmosphere when -the triple valve is in its restricted and normal release positions, and placed in communication with the train pipe and cut off from the atmosphere when the triple valve is moved to a position for causing the brakes to be applied, and means when the triple valve is in its retarded release position for restricting the iiow of air to the auxiliary reservoir.

11. In a triple valve having a piston actuated by variation in train pipe pressure, an auxiliary chamber positioned between the train pipe passage and the brake cylinder passage, means for closing communication between said passages, a service piston in said auxiliary chamber, means for communicating the service chamber with the auxiliary reservoir for actuating the piston, a service chamber positioned beneath said auxiliary chamber, a closure member having a medially f disposed tubular boss, a sleeve mounted in said boss, a poppet valve associated with said service chamber for controlling the passage of air from the train pipe to the said service chamber, said poppet valve having its stem extended into said chamber, said service piston having a depending stem extending through said sleeve and into engagement with the poppet valve stem and means upon the triple valve being moved to its service position to cause the actuation of the piston to permit train pipe pressure to pass into the service chamber.

12. In av triple valve having a piston actuated by variation in train pipe pressure, an auxiliary reservoir, a quick acting piston chamber adapted to communicate with the auxiliary reservoir and having a reciprocating piston operable by the auxiliary reservoir pressure, a service chamber, and a poppet valve chamber in constant communication with the train pipe through a restricted opening, said poppet valve chamber having a valve for controlling communication with said service chamber, said valve being operatively connected to said reciprocating piston to be actuated thereby and establish communication between the train pipe and the service chamber when the triple valve is in its service position.

13. A device to be applied to triple valves to produce quick service application including a quick action piston chamber having an insertable xed bushing for permanently closing the usual communication between said chamber and the brake cylinder, a service measuring chamber arranged to communicate selectively with the train pipe and the atmosphere, and means in said quick action piston chamber operable by the triple valve for communicating the service measuring chamber with the train pipe.

14. A device to be applied to triple valves to produce quick service application including a quick action piston chamber having an insertable fixed bushing for permanently closing the usual communication between said chamber and the brake cylinder, a service reservoir associated with the quick action piston chamber and arranged to communicate with the train pipe and the atmosphere, a valve for controlling the ilow of the uid from the train pipe to the service reservoir, and means in said quick action piston chamber operable by the triple valve for actuating said valve.

15. A device to be applied to triple valves to produce quick service application including a. quick action piston chamber having an insertable xed bushing for permanently closing the usual communication between said chamber and the brake cylinder, a service reservoir arranged to communicate with the train pipe and the atmosphere, a valve casing associated with the service reservoir and communicating with the train pipe, a valve in said valve casing for conducting the uid from the train pipe to the service reservoir, and means in said quick action piston chamber operable by the triple valve for actuating said valve to control the flow of the fluid from the train pipe to the service reservoir.

' BEST PRATT. 

